Observational constraints on Rastall's cosmology

Abstract

Rastall's theory is a modification of General Relativity, based on the non-conservation of the stress-energy tensor. The latter is encoded in a parameter γ such that γ = 1 restores the usual ∇ Tμ = 0 law. We test Rastall's theory in cosmology, on a flat Robertson-Walker metric, investigating a two-fluid model and using the type Ia supernovae Constitution dataset. One of the fluids is pressureless and obeys the usual conservation law, whereas the other is described by an equation of state px = wxx, with wx constant. The Bayesian analysis of the Constitution set does not strictly constrain the parameter γ and prefers values of wx close to -1. We then address the evolution of small perturbations and show that they are dramatically unstable if wx ≠ -1 and γ ≠ 1, i.e. General Relativity is the favored configuration. The only alternative is wx = -1, for which the dynamics becomes independent from γ.